TiO2反蛋白石光子晶体最新研究进展

doi:10.7517/j.issn.1674-0475.2018.01.002

摘要/Abstract

摘要： TiO₂反蛋白石光子晶体的研究近年来受到广大科技工作者的关注。它具有TiO₂的无毒、高折射率、良好的生物相容性，并且在电化学、光催化等方面有着优良的特性，而且具有光子晶体的光子带隙、光子局域、慢光效应、超棱镜效应、负折射效应等光学特性，使其在化学传感器、太阳能电池、光催化、高效率微波电线以及光子晶体纤维等方面具有广阔的应用前景。本文总结了TiO₂反蛋白石光子晶体的制备方法、改性方法，同时介绍了其近年来在各领域的应用研究进展。

关键词: TiO₂, 反蛋白石结构, 改性

Abstract: The study of TiO₂ inverse opal photonic crystal is concerned by the majority of scientists in recent years. It has the advantages of the titanium dioxide including non-toxic,the high refractive index, good biocompatibility, and excellent properties in electrochemistry, photo-catalysis, etc. And it also has optical properties of the band gap, photonic localization, slow light effect, super prism effect and negative refraction effect of the photonic crystal, which contributes to multitudinous potential applications in chemical sensors, solar cells, photo-catalysis, high efficient microwave wire,photonic crystal fiber, etc. In this paper,the preparation, modification and applications of the TiO₂ inverse opal photonic crystal in recent years were summarized.

Key words: TiO₂, inverse opal structure, modification

俞洁, 慈明珠, 鲁泉玲, 马舒晴, 姜丽, 雷菊英, 刘勇弟, 张金龙. TiO₂反蛋白石光子晶体最新研究进展[J]. 影像科学与光化学, 2018, 36(1): 14-32.

YU Jie, CI Mingzhu, LU Quanling, MA Shuqing, JIANG Li, LEI Juying, LIU Yongdi, ZHANG Jinlong. The Latest Research Progress of TiO₂ Inverse Opal Photonic Crystal[J]. Imaging Science and Photochemistry, 2018, 36(1): 14-32.

参考文献

[1] Schneider J, Matsuoka M, Takeuchi M, Zhang J L, Horiuchi Y, Anpo M, W.Bahnemann D. Understanding TiO₂ photocatalysis:mechanisms and materials[J]. Chemical Reviews, 2014, 114(19):9919-9986.
[2] Bose S, Soni V, Genwa K R. Recent advances and future prospects for dye sensitized solar cells:a review[J]. International Journal of Scientific Research Public, 2015, 5(4):1-9.
[3] Yang L, Jiang X, Ruan W, Zhao B, Xu W, Lombard J R. Observation of enhanced Raman scattering for molecules adsorbed on TiO₂ nanoparticles:charge-transfer contribution[J]. The Journal of Physical Chemistry C, 2008, 112(50):20095-20098.
[4] Yablonovitch E. Inhibited spontaneous emission in solid-state physics and electronics[J]. Physical Review Letters, 1987, 58(20):2059.
[5] John S. Strong localization of photons in certain disordered dielectric superlattices[J]. Physical Review Letters, 1987, 58(23):2486.
[6] 张友俊, 姬波, 王向前, 李英. 光子晶体及其应用[J]. 红外与激光工程, 2004, 33(3):320-322. Zhang Y J, Ji B, Wang X Q, Li Y. Photonic crystals and applications[J]. Infrared and Laser Engineering, 2004, 33(3):320-322.
[7] Collins G, Armstrong E, McNulty D, O'Hanlon S, Geaney H, O'Dwyer C. 2D and 3D photonic crystal materials for photocatalysis and electrochemical energy storage and conversion[J]. Science and Technology of advanced Materials, 2016, 17(1):563-582.
[8] Jin L, Huang X, Zeng G, Wu H, Morbidelli M. Conductive framework of inverse opal structure for sulfur cathode in lithium-sulfur batteries[J]. Scientific Reports, 2016, 6:32800.
[9] Blanco A, Chomski E, Grabtchak S, Ibisate M, John S, Leonard S W, Lopez C, Meseguer F, Miguez H, Mondia J P, Ozin G A, Toader O, Driel H M. Large-scale synthesis of a silicon photonic crystal with a complete three-dimensio-nal bandgap near 1.5 micrometres[J]. Nature, 2000, 405(6785):437-440.
[10] Halary-Wagner E, Wagner F R, Brioude A,Mugnier J, Hoffmann P. Light-induced CVD of titanium dioxide thin filmsⅡ:thin film crystallinity[J]. Chemical Vapor Deposition, 2005, 11(1):29-37.
[11] Moon J H, Cho Y S, Yang S M. Room temperature chemical vapor deposition for fabrication of titania inverse opals:fabrication, morphology analysis and optical characterization[J]. Bulletin of the Korean Chemical Society, 2009, 30(10):2245-2248.
[12] King J S, Graugnard E, Summers C J. TiO₂ inverse opals fabricated using low-temperature atomic layer deposition[J]. Advanced Materials, 2005, 17(8):1010-1013.
[13] King J S, Graugnard E, Summers C J. Photoluminescence modification by high-order photonic bandsin TiO₂/ZnS:Mn multilayer inverse opals[J]. Applied Physics Letters, 2006, 88(8):081-109.
[14] Alessandri I, Zucca M, Ferroni M, Bontempi Z,Laura E. Depero L E. Tailoring the pore size and architecture of CeO₂/TiO₂ core/shell inverse opals by atomic layer deposition[J]. Small, 2009, 5(3):336-340.
[15] Yan H, Yang Y, Fu Z, Yang B, Xia L, Xu Y, Fu S, Li F. Cathodic electrode position of ordered porous titania films by polystyrene colloidal crystal templating[J]. Che-mistry Letters, 2006, 35(8):864-865.
[16] Xu Y, Zhu X, Dan Y,Moon J H, Chen V W, Johnson A T, Perry J W, Yang S. Electrode position of three-dimensional titania photonic crystals from holographically patterned microporous polymer templates[J]. Chemistry of Materials, 2008, 20(5):1816-1823.
[17] Mihi A, Calvo M E, Anta J A,Míguez H. Spectral response of opal-based dye-sensitized solar cells[J]. The Journal of Physical Chemistry C, 2008, 112(1):13-17.
[18] Galusha J W, Tsung C K, Stucky G D, Bart M H. Optimizing sol-gel infiltration and processing methods for the fabrication of high-quality planar titania inverse opals[J]. Chemistry of Materials, 2008, 20(15):4925-4930.
[19] Li W, Wang F, Feng S, Wang J, Sun Z, Li B, Li Y, Yang J, Elzatahry A A, Xia Y, Zhao D. Sol-gel design strategy for ultradispersed TiO₂ nanoparticles on graphene for high-performance lithium ion batteries[J]. Journal of the American Chemical Society, 2013, 135(49):18300-18303.
[20] Wu M, Zheng A, Deng F, Su B L. Significant photocatalytic activity enhancement of titania inverse opals by anionic impurities removal in dye molecule degradation[J]. Applied Catalysis B:Environmental, 2013, 138:219-228.
[21] Qi D, Lu L, Wang L, Zhang J. Improved SERS sensitivity on plasmon-free TiO₂ photonic microarray by enhancing light-matter coupling[J]. Journal of the American Chemical Society, 2014, 136(28):9886-9889.
[22] Lu L, Teng F, Qi D, Wang L, Zhang J. Synthesis of visible-light driven Cr_xO_y-TiO₂ binary photocatalyst based on hierarchical macro-mesoporous silica[J]. Applied Catalysis B:Environmental, 2015, 163:9-15.
[23] Zhao Y, Yang B, Xu J, Fu Z, Wu Min, Li F. Facile synthesis of Ag nanoparticles supported on TiO₂ inverse opal with enhanced visible-light photocatalytic activity[J]. Thin Solid Films, 2012, 520(9):3515-3522.
[24] Liu J, Liu G, Li M, Shen W, Liu Z, Wang J, Zhao J, Jiang L, Song Y. Enhancement of photochemical hydrogen evolution over Pt-loaded hierarchical titania photonic crystal[J]. Energy & Environmental Science, 2010, 3(10):1503-1506.
[25] Wei N N, Han T, Deng G Z, Li J L, Du J Y. Synthesis and characterizations of three-dimensional ordered gold-nanoparticle-doped titanium dioxide photonic crystals[J]. Thin Solid Films, 2011, 519(8):2409-2414.
[26] Li Q, Shang J K. Inverse opal structure of nitrogen-doped titanium oxide with enhanced visible-light photocatalytic activity[J]. Journal of the American Ceramic Society, 2008, 91(2):660-663.
[27] Xu J, Yang B, Wu M, Fu Z,Lv Y, Zhao Y. Novel N-F-codoped TiO₂ inverse opal with a hierarchical meso-/macroporous structure:synthesis, characterization, and photocatalysis[J]. The Journal of Physical Chemistry C, 2010, 114(36):15251-15259.
[28] Deng L E, Wang Y S, Fu M, Liu W Y. Spontaneous emission of Tb³⁺ doped in TiO₂ inverse opal[J]. Nanoscience and Nanotechnology Letters, 2013, 5(2):314-316.
[29] Yang Z, Zhu K, Song Z, Zhou D, Yin Z, Qiu J. Preparation and upconversion emission properties of TiO₂:Yb, Er inverse opals[J]. Solid State Communications, 2011, 151(5):364-367.
[30] Cho C Y, Lee S, Lee J, Lee D C, Moon J H. Tetrapod CdSe-sensitized macroporous inverse opal electrodes for photo-electrochemical applications[J]. Journal of Materials Chemistry A, 2014, 2(41):17568-17573.
[31] Cheng C, Karuturi S K, Liu L, Liu J, Li H, Su L T, Tok A Y, Fan H J. Quantum-dot-sensitized TiO₂ inverse opals for photoelectrochemical hydrogen generation[J]. Small, 2012, 8(1):37-42.
[32] Xiong Y, Deng F, Wang L, Liu Y. TiO₂ inverse opal based CdS/CdSe quantum dot co-sensitized solar cells[J]. Journal of Materials Science:Materials in Electronics, 2014, 25(7):3039-3043.
[33] Kim H N, Moon J H. Enhanced photovoltaic properties of Nb₂O₅-coated TiO₂ 3D ordered porous electrodes in dye-sensitized solar cells[J]. ACS Applied Materials & Interfaces, 2012, 4(11):5821-5825.
[34] Lee S, Lee Y, Kim D H, Moon H K. Carbon-deposited TiO₂ 3D inverse opal photocatalysts:visible-light photocatalytic activity and enhanced activity in a viscous solution[J]. ACS Applied Materials &Interfaces, 2013, 5(23):12526-12532.
[35] Liao G, Chen S, Quan X, Chen H,Zhang Y. Photonic crystal coupled TiO₂/polymer hybrid for efficient photocatalysis under visible light irradiation[J]. Environmental Science & Technology, 2010, 44(9):3481-3485.
[36] Du J, Lai X, Yang N, Zhai J, Kisailus D, Su F, Wang D, Jiang L. Hierarchically ordered macro-mesoporous TiO₂-graphene composite films:improved mass transfer, reduced charge recombination, and their enhanced photocatalytic activities[J]. ACS Nano, 2010, 5(1):590-596.
[37] Park Y, Lee J W, Ha S J, Moon J H. 1D nanorod-planted 3D inverse opal structures for use in dye-sensitized solar cells[J]. Nanoscale, 2014, 6(6):3105-3109.
[38] Li J, Liu Q, Chen H, Wei H, Gu Z, Xie B. Fabrication of TiO₂ inverse opal film and its application in chemical sensor[J]. Acta Chimica Sinica-Chinese Edition, 2006, 64(14):1489.
[39] Kuo C Y, Lu S Y, Chen S, Bernards M, Jiang S. Stop band shift based chemical sensing with three-dimensional opal and inverse opal structures[J]. Sensors and Actuators B:Chemical, 2007, 124(2):452-458.
[40] Li J, Zheng T. A comparison of chemical sensors based on the different ordered inverse opal films[J]. Sensors and Actuators B:Chemical, 2008, 131(1):190-195.
[41] Chiang C C, Tuyen L D, Ren C R, Chau L, Wu C Y, Huang P, Hsu C C. Fabrication of titania inverse opals by multi-cycle dip-infiltration for optical sensing[J]. Photonics and Nanostructures-Fundamentals and Applications, 2016, 19:48-54.
[42] Liu C, Gao G, Zhang Y, Wang L, Wang J, Song Y. The naked-eye detection of NH₃-HCl by polyaniline-infiltrated TiO₂ inverse opal photonic crystals[J]. Macromolecular Rapid Communications, 2012, 33(5):380-385.
[43] Xie Y, Meng Y, Wu M. Visible-light-driven self-cleaning SERS substrate of silver nanoparticles and graphene oxide decorated nitrogen-doped titania nanotube array[J]. Surface and Interface Analysis, 2016, 48:334-340.
[44] Musumeci A, Gosztola D, Schiller T, Dimitrijevic N M, Mujica V, Martin D, Rajh T. SERS of semiconducting nanoparticles (TiO₂ hybrid composites)[J]. Journal of the American Chemical Society, 2009, 131(17):6040-6041.
[45] Qi D, Yan X, Wang L,Zhang J. Plasmon-free SERS self-monitoring of catalysis reaction on Au nanoclusters/TiO₂ photonic microarray[J]. Chemical Communications, 2015, 51(42):8813-8816.
[46] Lee J W, Lee J, Kim C, Cho C Y, Moon J H. Facile fabrication of sub-100 nm mesoscale inverse opal films and their application in dye-sensitized solar cell electrodes[J]. Scientific Reports, 2014, 4:6804.
[47] Chen J I L, von Freymann G, Choi S Y, Kitaev V, Ozin G A. Amplified photochemistry with slow photons[J]. Advanced Materials, 2006, 18(14):1915-1919.
[48] Sordello F, Duca C, Maurino V, Minero C. Photocatalytic metamaterials:TiO₂ inverse opals[J]. Chemical Communications, 2011, 47(21):6147-6149.
[49] Qi D Y, Lu L J, Xi Z H, Wang L Z, Zhang J L. Enhanced photocatalytic performance of TiO₂ based on synergistic effect of Ti³⁺ self-doping and slow light effect[J]. Applied Catalysis B:Environmental, 2014, 160:621-628.
[50] Kim K, Thiyagarajan P, Ahn H J, Kim S I, Jang J H. Optimization for visible light photocatalytic water splitting:gold-coated and surface-textured TiO₂ inverse opal nano-networks[J]. Nanoscale, 2013, 5(14):6254-6260.
[51] 顾培夫, 黄弼勤, 郑臻荣. 用于可见光区的薄膜光子晶体全角度反射器[J]. 物理学报, 2005, 54(8):3707-3710. Gu P F,Huang B Q,Zheng Z R. Photonic crystal film omnidirectional reflector used withinvisiblelight range[J]. Acta Physica Sinica, 2005, 54(8):3707-3710.
[52] Liang Z, Zheng G, Li W, She Z W,Yao H,Yan K,Kong D,Cui Y. Sulfur cathodes with hydrogen reduced titanium dioxide inverse opal structure[J]. ACS Nano, 2014, 8(5):5249-5256.

TiO₂反蛋白石光子晶体最新研究进展

The Latest Research Progress of TiO₂ Inverse Opal Photonic Crystal

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	王凌云, 谭侃, 罗静. 单宁酸改性制备光敏碳纳米管及UV光固化AESO复合膜的制备[J]. 影像科学与光化学, 2019, 37(3): 175-184.
[2]	李玥, 李红英, 常玉雪, 周宏艳, 于翔. MoS₂/TiO₂纳米管阵列的一步沉积法制备及光电性能研究[J]. 影像科学与光化学, 2018, 36(4): 331-339.
[3]	邓亚峰, 周奕华, 钱俊, 罗妍, 吴丽辉. 基于上转换发光的碳量子点制备及应用研究[J]. 影像科学与光化学, 2017, 35(6): 884-893.
[4]	田野, 朱萌, 牛忠伟. 烟草花叶病毒的特定位点改性及应用[J]. 影像科学与光化学, 2017, 35(4): 494-505.
[5]	扶浩, 杨建文, 刘晓暄. 光点击化学修饰石油树脂研究[J]. 影像科学与光化学, 2016, 34(4): 380-387.
[6]	张国强, 曲丹, 苗湘, 张晓燕, 孙再成. CdS超薄片层包覆TiO₂中空结构复合材料的形成和应用[J]. 影像科学与光化学, 2015, 33(5): 374-382.
[7]	史丽娜, 曲阳, 李志君, 孙莉群, 井立强. TiO₂/Bi₂O₃纳米复合体的制备及可见光催化产氢性能[J]. 影像科学与光化学, 2015, 33(5): 426-433.
[8]	张纪伟, 金振声, 张经纬, 李秋叶, 张治军. 富含本征缺陷的新型锐钛矿TiO₂纳米管的制备[J]. 影像科学与光化学, 2015, 33(4): 285-291.
[9]	李秋叶, 金振声. 可见光“全”分解水的类纳光电化学(PEC)电池模型[J]. 影像科学与光化学, 2015, 33(2): 99-107.
[10]	张鹏, 于彦龙, 匡元江, 姚江宏, 曹亚安. Si掺杂TiO₂催化剂的结构与可见光催化活性研究[J]. 影像科学与光化学, 2013, 31(4): 295-304.
[11]	韩严和, 姜金海, 蒋丽, 李宝琴, 刘璐, 陈家庆, 梁存珍. 阴离子对TiO₂晶形的影响及光催化性能研究[J]. 影像科学与光化学, 2013, 31(3): 186-196.
[12]	付华, 韩爱霞. 改性直接灰D金属螯合物偏光膜的制备及其偏光性质研究[J]. 影像科学与光化学, 2013, 31(3): 208-214.
[13]	刘红波, 林峰, 肖望东, 徐玲, 张武英. 有机硅改性丙烯酸环氧单酯光-热混杂固化体系的表面性能[J]. 影像科学与光化学, 2013, 31(2): 125-131.
[14]	赖俊伟, 杨建文, 刘晓暄. 碳酸钙表面感光修饰及其在UV涂料中的应用[J]. 影像科学与光化学, 2013, 31(1): 10-17.
[15]	袁静, 安振国, 张敬杰, 李冰. 空心玻璃微珠/TiO₂复合微球的制备及其性能研究[J]. 影像科学与光化学, 2012, 30(6): 447-455.